18 Clinical Trials for Various Conditions
Background: - When bacteria enter the lungs, serious infections can occur. Researchers want to learn more about the process of inflammation in the lungs by studying lung cells and the products that they make. Lung cells are influenced by infections, smoking, and molecules made within the body. Researchers also want to learn more about one of these molecules, called microRNA (or micro ribonucleic acid). Objective: - To better how the body responds to infection. Also, to understand which cells in the lung secrete microRNA and how they may influence other lung cells. Eligibility: - Healthy, non-smoking adults ages 18-45. Design: * Participants will be screened with a medical history and physical exam. They will have blood and urine tests and an electrocardiogram. * Participants will have blood drawn from an arm vein. They will have an intravenous catheter (small plastic tube) placed in a vein. * All participants will have bronchoscopy with bronchoalveolar lavage. They will be numbed with medicine. A thin flexible tube will be placed through the nasal passages or the mouth into the airways of the lung. * Some participants will have bronchoscopy with bronchoalveolar lavage (rinsing the airways with salt water) in order to obtain cells from lung. The water will then be suctioned out. * Some participants will have two bronchoscopies; during the first procedure, endotoxin, a molecule found in bacteria is squirted into a small portion of the lung. Endotoxin is a molecule that acts like an infection but isn t one. After 6 to 48 hours, bronchoscopy with with bronchoalveolar lavage will be done to look at the lung s response to endotoxin. * Participants heart rhythm and rate, temperature and blood oxygen level will be monitored during the procedures. * Participants will be called the next day to see how they are feeling.
Pulmonary contusion (PC) is a significant problem after blunt trauma that may often lead to acute respiratory distress syndrome (ARDS) and in some patients, death. Although the pathophysiology is incompletely understood, it is clear that there is a biochemical process involving changes in the inflammatory milieu after contusion which occurs in addition to simple direct mechanical injury to the lung. The relationship of severity of contusion on imaging, disturbances in the inflammatory phenotype, and outcome is unknown. This is a prospective, observational study which will evaluate the size and severity of contusion as measured on chest computed tomography (CT). Inflammatory mediators will be measured in the bronchoalveolar lavage (BAL) and in the serum of patients with pulmonary contusion to define the inflammatory nature of the post-contusion lung. The degree of abnormality within the inflammatory parameters will be correlated with lung contusion size and subsequent patient outcomes. These data will be compared to other patient groups: 1) Trauma patients without chest injury who are mechanically ventilated; 2) Uninjured patients undergoing elective surgical procedures that will require intubation and mechanical ventilation; 3) Patients in the Medical ICU who are mechanically ventilated with acute respiratory failure. The hypothesis tested within this study is resolution of lung injury is dependent upon the presence of Tregs in the alveolar space.
An informational evaluation of COVID-19 patients who receive low-level laser therapy in addition to a normal regimen of treatment for symptoms associate with COVID-19. Results are compared to statistical observations published in literature from patients receiving standard care for COVID-19 symptoms without low-level laser therapy.
This is a multicenter, randomized, double-blind, parallel group study to investigate the efficacy of pemziviptadil (PB1046) by improving the clinical outcomes in hospitalized COVID-19 patients at high risk for rapid clinical deterioration, acute respiratory distress syndrome (ARDS) and death. The study will enroll approximately 210 hospitalized COVID-19 patients who require urgent decision-making and treatment at approximately 20 centers in the United States.
The purpose of this research study is to gain understanding of the basic responses of the lungs to inflammation and specifically if there may be a better way to detect graft inflammation using non-invasive methods as well as to determine the effectiveness of immunosuppressive treatment regimens in preventing acute rejection in lung transplant recipients.
Acute lung injury (ALI) is an often deadly form of respiratory failure caused by inflammation. The widespread injury to the lungs involves a build-up of fluid in the lungs that results in damage to the lungs and a decreased ability of the lungs to function properly. There is currently no specific treatment for ALI; and of the 200,000 cases reported in the US yearly, about 40% will die. Some patients may have other conditions that could change the risk of developing ALI. For example, it has been reported that patients who have septic shock have a lower chance of developing ALI if they also have diabetes mellitus (diabetes). Septic shock is a type of infection that causes overwhelming inflammation to occur throughout the body; it increases the chances that a person will develop ALI. The reason diabetics are less likely to develop ALI is unclear and deserves further investigation. The investigators believe that it may be explained by differences in the way certain cells that are involved in inflammation function in the lungs. The investigators plan on looking at the relationship between the wide-spread inflammation that occurs within the bodies of diabetic and non-diabetic patients with an increased chance of developing ALI \[sepsis\]. To study this relationship, we will identify patients who fit the requirements of the study. The investigators will obtain blood samples and lung washings from these patients. The lung washings will be obtained by injecting clean salt water into the lungs through a tube and then pulling the water back out. When the sterile water is removed, some cells from the lungs also are removed and they can then be used for further lab studies. Determining how diabetes may change a patient's chance of developing ALI may uncover useful information that may help prevent or treat ALI in all patients at risk.
Despite decades of research, the mortality in acute lung injury remains very high and treatment options are very limited. Given these facts, the best treatment modality may be in prevention of this lethal syndrome. Historically, imaging has played a crucial role in understanding ALI. The appearance of chest radiography is one of the consensus criteria in defining ALI, and commuted tomography (CT) scans further advanced the understanding of the pathoanatomy of ALI. While valuable, these imaging modalities are nonspecific and do not incorporate functional cellular physiology. PET imaging measures concentrations of radioisotopes in the body. By embedding in, but not altering molecules, the natural fate of these tracers can be studied with PET imaging. Advances in the understanding of ALI include blood flow distribution, as well as the response to alveolar recruitment maneuvers and prone positioning. Not all patients who are receiving mechanical ventilation develop ALI. Inflammation in the lungs is known to play a key early role in the development and progression of ALI. Secondary to inflammation, the lungs develop edema and do not exchange oxygen as well. This early inflammation is in part driven by a specific type of immune cell called the neutrophil. These cells seem to travel and become sequestered in the lung- they are "recruited" to the lung during this inflammatory stage. When there, these neutrophils release inflammatory substances which are integral in the development of ALI. Neutrophils use primarily glucose as a fuel source. The radio isotope \[18F\]Fluorodeoxyglucose (FDG)is a glucose analog and therefore taken up/ingested by the neutrophils as a part of their normal metabolism. Because of this fact, positron emission tomography (PET) using the radio isotope \[18F\]FDG is a highly sensitive marker to look at the recruitment of neutrophils to the lung, therefore quantifying the degree of pulmonary inflammation prior to the development of ALI. The investigators seek to examine the relationship of pulmonary inflammation in patients at risk for ALI, but without clinical evidence of the syndrome. The investigators seek to enroll ten patients in a pilot trial.
Acute lung injury (ALI) and acute respiratory distress syndrome (ARDS) are devastating disorders associated with lung inflammation, low oxygen levels and respiratory failure in children. Prevalence of ALI ranges from 2.2 to 12 per 100,000 children per year. Using these estimates, up to 9,000 children each year will develop ALI/ARDS, which may cause upto 2,000 deaths per year. Currently, there are no specific therapies directed against ARDS/ALI in children. In adult patients, use of steroids early in the course of ARDS appears promising. There are no published clinical trials examining the use of steroids for the treatment of ALI/ARDS in children. Hypothesis: Subjects with ALI/ARDS receiving steroids early in the course of disease (within 72 hours) and longer than 7 days will have improved clinical outcomes as compared to placebo control group as defined by (a) a decreased duration of mechanical ventilation and (b) significantly increased PaO2/FiO2 ratios.
Acute lung injury (ALI)/Acute Respiratory Distress Syndrome (ARDS) is a severe lung condition that causes respiratory failure. This study will examine if differences in genes and biomarkers involved in the inflammation and blood clotting process may affect the severity of and recovery from ALI/ARDS in children hospitalized with the condition.
This Phase 2 study will evaluate the efficacy, safety, pharmacodynamics and pharmacokinetics of inhaled TD-0903 compared with a matching placebo in combination with standard of care (SOC) in hospitalized patients with confirmed COVID-19 associated acute lung injury and impaired oxygenation.
Acute lung injury (ALI) and the more severe manifestation, acute respiratory distress syndrome (ARDS) describe syndromes of acute onset, bilateral, inflammatory pulmonary infiltrates and impaired oxygenation. ARDS/ALI are a continuum of disease which results in a life threatening, rapidly progressive illness and occurs in critically ill patients. Recent reports in the Journal of the American Medical Association (JAMA) highlight the significant public health impact ARDS/ALI has on the critically ill population in that despite robust research efforts, these illnesses continue to be under diagnosed, under treated, and continue to have a high mortality rate (≥ 40% of all confirmed diagnoses). The estimates for ARDS/ALI incidence vary due to inconsistencies with proper diagnosis and lack of valid biomarkers of disease; however, it is expected that anywhere from 20-50% of patients on mechanical ventilation will develop this disease. Previous work by our group has shown that sphingolipids play a multifaceted role in lung inflammation. Sphingolipid are a class of bioactive lipids that play a role in cellular processes such as apoptosis, cell migration, and adhesion. Ceramide is one species of sphingolipid the investigators have examined in both man and mouse. Our laboratory has shown that ceramide is up-regulated in pulmonary inflammation in mouse models of pneumonitis and is elevated in the exhaled breath condensate of mechanically ventilated patients at risk for ARDS/ALI. Our work coupled with the work of others highlighting a role for ceramide in chronic obstructive pulmonary disease (COPD), surfactant dysfunction, and infectious disease make ceramide a logical candidate biomarker that warrants further investigation. To our knowledge, there are no studies examining the role of ceramide as a biomarker in ARDS/ALI. Thus, our overarching hypothesis is that ceramide is elevated in the lungs of patients who develop ARDS/ALI. This lipid dysregulation accounts for the pathophysiology seen in this disease and may be a potential pharmacologic target for clinical treatment. Thus the purpose of this exploratory research is to maximize existing specimens to further evaluate ceramide as a biomarker for acute lung injury.
Pragmatic, Randomized, Optimal Platelet and Plasma Ratios (PROPPR)is a Phase III trial designed to evaluate the difference in 24-hour and 30-day mortality among subjects predicted to receive massive transfusion (\[MT\] (defined as receiving 10 units or more red blood cells (RBCs) within the first 24 hours). The goal of PROPPR is to improve the basis on which clinicians make decisions about transfusion protocols for massively bleeding patients. PROPPR is a Resuscitation Outcomes Consortium (ROC) Protocol. ROC is funded by the National Heart, Lung, and Blood Institute (NHLBI), the United States' Department of Defense (DoD) and the Defence Research and Development Canada. PROPPR will be conducted as a Phase III trial at Level I Adult Trauma Centers in North America.
Purpose: The primary purpose of this study is to measure pulmonary function, symptoms, and pulmonary inflammatory responses in healthy young adults during and immediately after exposure to a low concentration of ozone (0.070 ppm) or clean air for 6.6 hours while undergoing moderate intermittent exercise. This concentration is the current EPA NAAQS standard for ozone.
This research is being done to determine if there is a way the investigators can improve the techniques that they use to assist patients with their breathing during surgery. The majority of surgeries require patients to concurrently undergo general anesthesia. This usually includes a breathing tube and a machine that breathes for the patient during the duration of the surgery. The doctors would like to investigate the effects of this type of anesthesia to healthy adult patients and whether they can improve the way they give general anesthesia to patients. The investigators plan to ask approximately 200 patients to participate. If the patients decide to participate in the study,some additions will be made to the standard anesthetic care they receive. The patients will additionally be monitored for adequate oxygenation in their blood as well as level of inflammation in their blood and lungs. The patients' breathing tube will be bathed with warm normal saline and suctioned twice during the operation. When these procedures are done the patients will be asleep and not be aware of what is happening.
This is a quality improvement study with the purpose of observing and measuring the effects of implementation of a proven standardized lung protective ventilation protocol in the new electronic medical record system iCentra across all Intermountain Healthcare hospitals. Approximately 14,000 records will be accessed for this study from a database of mechanically ventilated patients established for quality improvement purposes. The investigators hypothesize that implementation of a standardized computerized lung protective ventilation protocol across all Intermountain Healthcare hospitals will be feasible, will decrease initial tidal volumes to the target 6 ml/kg PBW, and will improve outcomes. The objectives of this study are to: * Determine if the implementation of lung protective ventilation (with a 6 ml/kg PBW tidal volume ventilation protocol on initiation of mechanical ventilation) improves outcomes in patients with acute respiratory failure requiring mechanical ventilation * Determine if the implementation of lung protective ventilation (with a 6 ml/kg PBW tidal volume ventilation protocol on initiation of mechanical ventilation) improves outcomes in the sub-group of patients with the acute respiratory distress syndrome (ARDS) * Measure compliance with the implementation of a computerized lung protective ventilation protocol at 12 Intermountain Healthcare hospitals
This is a Phase 2, multicenter study in adult participants with an acute COPD exacerbation and type 2 inflammation
Background: COVID-19 virus infection differs among people. Some people have no or mild symptoms. For others, COVID-19 is life threatening and causes damage to the body s organs. Researchers want to better understand the virus to learn how to kill it. Objective: To understand how the COVID-19 virus causes wide differences in how sick one can become from the infection. Eligibility: People ages 18-80 with COVID-19 infection Design: Participants will be screened with a review of their medical records. Participants who enter the study at the beginning of their COVID-19 infection will stay in the hospital until they are healthy enough to go home. Those who enter after they have recovered may need to stay in the hospital 1-2 nights to perform the study tests. Participants will have MRI and CT scans of the brain, heart, and lungs. They will lie in a machine that takes pictures of the body. For the MRI, soft padding or a coil will be placed around their head and chest. They may receive a dye injected into a vein. Participants will have an ultrasound of the kidneys and heart. Participants will provide blood and urine samples. They will provide nasal swabs. Participants will have a bronchoscopy. A thin tube will be placed through the nose or mouth into the airway. Saltwater will be squirted into the lungs and removed by suction. Participants may provide a spinal fluid sample. A needle injected into the spinal canal will obtain fluid. Participants will have lung and heart function tests. At various points after recovery, participants will repeat many of these tests. ...
This study is a longitudinal single-center pilot study designed to describe changes in lung function and levels of noninvasive biomarkers of airway inflammation in children ages 6-18 years over two months following hospitalization for an acute exacerbation of asthma. Forty children ages 6-18 years with asthma who are admitted to Children's Hospital and Regional Medical Center (GCRC) for an asthma exacerbation will be enrolled and complete an initial study visit prior to hospital discharge. Children with asthma will be recruited from the inpatient medical unit. During their initial visit subjects will undergo a clinical assessment and perform spirometry to measure lung function. In addition, exhaled nitric oxide (eNO) concentration will be measured and a sample of exhaled breath condensate (eBC) will be collected during 20 minutes of tidal breathing. Breath condensate will be analyzed to determine the concentration of cysteinyl leukotrienes (CysLT), an important mediator of airway inflammation in asthma. Subjects with asthma will return to the GCRC pediatric satellite at Seattle Children's Hospital for follow-up study visits at 1 week, 2 weeks, and 4 weeks following hospital discharge. During follow-up visits subjects will complete a questionnaire regarding symptoms and medication use since the most recent study visit, will perform spirometry, and have eNO concentration measured and breath condensate collected for CysLT analysis. The aims of this observational study are to: 1. Assess the association of levels of exhaled nitric oxide and cysteinyl leukotrienes in breath condensate with measures of airflow obstruction (FEV1) and asthma symptoms during, and at one, two, and four weeks following hospital discharge for asthma exacerbation. 2. Compare levels of exhaled nitric oxide and cysteinyl leukotrienes in breath condensate from children ages 6-18 years hospitalized for status asthmaticus to levels from age-matched healthy control subjects without asthma.